JP5405240B2 - Waterproof structure of levers in power tools - Google Patents

Description

  The present invention relates to a waterproof structure of a rotation support portion of a forward / reverse switching lever, for example, in a hand-held electric screw tightener.

The electric screw tightener (electric screwdriver) includes a tool main body with an electric motor and a handle provided so as to protrude sideways from the side of the tool main body, and is provided at the base of the handle. When the trigger switch lever is pulled with your fingertip, the switch knob on the switch body built in the handle is pressed to activate the electric motor, and the screwdriver bit attached to the spindle at the tip of the tool body is screwed. Rotate in the direction. In this type of screw tightening machine, the spindle can be rotated in the screw loosening direction by reversing the electric motor in order to cope with the screw loosening operation.
The switch body incorporated in the handle has an on / off circuit and forward / reverse switching circuit for the electric motor. The switch knob protruding from the side of the switch body is moved on and off by moving the trigger switch lever back and forth. In addition, the contact part arranged at the upper part of the switch body is configured to be switched by rotating the forward / reverse switching lever to the left and right, and the normal forward / reverse switching lever is normally rotatably supported at the upper part of the switch body to form an assembly. Has been.
Conventionally, techniques for enhancing waterproofness or dustproofness of a switch body and levers for operating the switch body are disclosed in the following patent documents.

JP-A-9-320398 JP 2001-110271 A JP 9-17280 A Japanese Examined Patent Publication No. 7-43977

However, the conventional techniques disclosed in these patent documents are for the switch body, and the waterproof structure for the forward / reverse switching lever is insufficient. The switch body, which has a half-split structure with built-in on / off circuit inside, is sealed by being welded or bonded together, while it is securely waterproof and dustproof, it is operated with a forward / reverse switching lever. Since the contact part of the forward / reverse switching circuit is exposed at the upper part of the switch body, it must be securely waterproofed.
The present invention is directed to, for example, a forward / reverse switching lever that is rotated to the left and right, and has a higher waterproof performance than a conventional lever that is provided on the switch body so as to be rotatable.

For this reason, the present invention has a waterproof structure having the structure described in each claim.
According to the waterproof structure of the first aspect, the waterproofing performance of the lever is enhanced as compared with the conventional structure since the waterproofing of the rotation support portion of the lever is performed by the packing.
In addition, the rotation support portion is the center of the rotation operation of the lever, and the movement range is limited compared to the tip end portion of the lever. Sealing can be performed efficiently with the packing, and thus the waterproof structure can be made compact.
In this specification, the waterproof performance refers to a function of preventing the entry of foreign matter into the switch case, and the foreign matter includes not only moisture but also all foreign matters such as dust and dust.
The lever includes a forward / reverse switching lever in a screw tightener, for example. The lever includes a lever that is rotated in the horizontal direction (left-right direction), the up-down direction, and the like via the rotation support portion.
According to the waterproof structure of the second aspect, the labyrinth structure is formed between the packing and the groove portion, and the waterproof performance of the rotation support portion is further enhanced.
According to the waterproof structure of the third aspect, since the maze structure is formed between the two grooves and the packing fitted in each, and a more complicated maze structure is formed, the waterproof performance can be further enhanced. .
According to the waterproof structure of the fourth aspect, since both end portions of one packing are fitted into the groove portions to form a maze structure, a complicated maze structure is formed between the packing and the rotation support portion. Its waterproof performance is further enhanced.
According to the waterproof structure of claim 5, a maze structure is formed between one convex portion and two packings mounted on both sides thereof, and the waterproof performance between the packing and the rotation support portion is further enhanced. It is done.
According to the waterproof structure of the sixth aspect, a maze structure is formed between the packing and the convex portion, and the waterproof performance between the packing and the rotation support portion is further enhanced.
According to the waterproof structure of the seventh aspect, a maze structure is formed between the switch case and the packing, and the waterproof performance between the two is further enhanced.
According to the waterproof structure of the eighth aspect, the sealing resin and the durability can be further enhanced by covering the rotational support portion with the elastomer resin layer by integral molding. The elastomer resin layer can be integrally formed and covered around the rotation support portion by so-called two-color molding when the lever is molded. Further, instead of or in addition to this, an elastomer resin layer may be integrally formed and covered on the case side that rotatably supports the rotation support portion.
According to the waterproof structure of the ninth aspect, the absorbing member prevents entry of foreign matter such as moisture and dust into the switch case.

It is a whole side view of an electric screw fastening machine. In this figure, a switch having a forward / reverse switching lever is indicated by a solid line, and the entire electric screw tightener is indicated by a two-dot chain line. It is a side view of a switch body concerning an embodiment of the present invention. In this figure, the upper side of the switch body is broken to show its internal structure. This figure shows the waterproof structure of the first embodiment. It is an enlarged view of the (III) part in FIG. This figure has shown the rotation support part of a switching lever, and its periphery. This figure shows the waterproof structure of the first embodiment. It is a figure which shows the waterproof structure of 2nd Embodiment, Comprising: It is a side view of the rotation support part of a lever, and its periphery. It is a figure which shows the waterproof structure of 3rd Embodiment, Comprising: It is a side view of the rotation support part of a lever, and its periphery. It is a figure which shows the waterproof structure of 4th Embodiment, Comprising: It is a side view of the rotation support part of a lever, and its periphery. It is a figure which shows the waterproof structure of 5th Embodiment, Comprising: It is a side view of the rotation support part of a lever, and its periphery. It is a figure which shows the waterproof structure of 6th Embodiment, Comprising: It is a side view of the rotation support part of a lever, and its periphery. It is a figure which shows the waterproof structure of 7th Embodiment, Comprising: It is a side view of the rotation support part of a lever, and its periphery. It is a figure which shows the waterproof structure of 8th Embodiment, Comprising: It is a side view of the rotation support part of a lever, and its periphery. It is a figure which shows the waterproof structure of 9th Embodiment, Comprising: It is a side view of the rotation support part of a lever, and its periphery.

Next, an embodiment of the present invention will be described with reference to FIGS. FIG. 1 shows a switch body 10 having a waterproof structure according to the first embodiment and an electric screw tightener 1 having the switch body 10. The switch body 10 is incorporated in the handle portion 3 of the electric screw tightener 1. The handle part 3 is provided in a state of protruding from the side of the tool body part 2 to the side. The switch body 10 is incorporated in the vicinity of the base part of the handle part 3 (on the tool body part side). The tool body 2 includes an electric motor 4 as a drive source and a screw tightening mechanism (not shown) that is operated by the rotational power of the electric tool.
The switch body 10 includes a switch lever 11 for turning on and off the power supply circuit of the electric motor 4. The switch lever 11 is disposed so as to protrude from the front surface of the handle portion 3. When the user pulls the switch lever 11 with the fingertip of the hand holding the handle portion 3, the switch body 10 is turned on. When the switch body 10 is turned on, the power circuit is turned on and the electric motor 4 is activated. A rechargeable battery pack 5 is attached to the tip of the handle portion 3. The electric motor 4 is activated using the battery pack 5 as a power source.
FIG. 2 shows details of the switch body 10. The switch body 10 includes a rectangular box switch case 13. The switch case 13 is formed by abutting and joining halved resin cases, and a necessary circuit board and the like are accommodated therein. A switch rod 12 protrudes from the front portion of the switch case 13. A switch lever 11 is attached to the tip of the switch rod 12. The basic configuration of the switch main body 10 is a conventionally known technique, and no specific changes are required in the present embodiment, so detailed description thereof is omitted.

A forward / reverse switching lever 15 is provided on the upper portion of the switch body 10. The forward / reverse switching lever 15 is rotated when switching the forward direction or the reverse direction so that the rotation direction of the electric motor corresponds to when the screw is tightened or loosened. The forward / reverse switching lever 15 is tilted in a certain angular range in the left-right direction (the direction orthogonal to the paper surface in FIG. 2) to switch the rotation direction of the electric motor. The forward / reverse switching lever 15 can be turned left and right by the fingertip of the hand holding the handle portion 3 by the user. The forward / reverse switching lever 15 is an example of a lever described in the claims, and this embodiment is characterized by a waterproof structure of the forward / reverse switching lever 15.
The forward / reverse switching lever 15 includes an operation portion 15a that extends forward from the inside of the handle portion 3, an operating portion 15b that enters the switch case 13 of the switch body 10, and a cylindrical support that couples the two. A portion 15c is provided. A cylindrical support recess 13 a is provided in the vicinity of the upper front corner of the switch case 13. The forward / reverse switching lever 15 is supported on the upper portion of the switch case 13 in a state where the rotation support portion 15c is accommodated in the support recess 13a. The operation unit 15a extends forward from above the support recess 13a. The operating portion 15b extends into the switch case 13 through an insertion window portion 13b provided in the support recess 13a. FIG. 3 shows details of the rotation support portion 15c and its surroundings.

A rotation support portion 15c having a cylindrical body shape is accommodated in a support concave portion 13a also having a cylindrical body shape, and the switching lever 15 is supported so as to be tiltable to the right and left within a certain angular range. A packing 16 is attached to the rotation support portion 15c. In the present embodiment, a so-called O-ring (rubber ring) is illustrated as the packing 16. The forward / reverse switching lever 15 is tilted right and left about the rotation support portion 15c with the packing 16 slidingly contacting the inner surface of the support recess 13a. When the packing 16 is brought into sliding contact with the inner surface of the support recess 13a, the inside of the support recess 13a is sealed. Sealing the inside of the support recess 13a with the packing 16 prevents foreign matter such as moisture and dust from entering the switch case 13 through the insertion window portion 13b.
FIG. 4 shows the waterproof structure of the second embodiment. The second embodiment is different from the first embodiment in that the packing 16 is accommodated in a groove 20 provided in the rotation support portion 15c. About the point similar to 1st Embodiment, the description is abbreviate | omitted using a code | symbol of a peer. The groove part 20 is formed over the entire periphery of the rotation support part 15c. The packing 16 is in sliding contact with the inner surface of the support recess 13a in a state of being fitted along the groove 20.
By inserting the packing 16 into the groove portion 20, a labyrinth structure (a structure in which a foreign substance intrusion path is bent) is formed between the packing 16 and the rotation support portion 15c. For this reason, in 2nd Embodiment, the waterproof performance between the packing 16 and the rotation support part 15c is further improved.

The maze structuring can be implemented in various forms. For example, FIG. 5 shows a waterproof structure of the third embodiment. In the third embodiment, two groove portions 21 and 22 are provided in the rotation support portion 15 c of the forward / reverse switching lever 15. The two groove portions 21 and 22 are formed in parallel to each other at a predetermined interval in the axial direction of the rotation support portion 15c and over the entire circumference. A packing 16 is fitted along each of the groove portions 21 and 22. The two packings 16 and 16 are slidably contacted with the inner surface of the support recess 13a. According to such a configuration, a more complicated labyrinth structure is formed between the two packings 16 and 16 and the rotation support portion 15c, so that the waterproof function between the two packings 16 and 20 can be further enhanced.
FIG. 6 shows the waterproof structure of the fourth embodiment. In the fourth embodiment, two packings 16 and 16 are mounted along both sides of the annular convex portion 23 provided in the rotation support portion 15c. The convex portion 23 is provided over the entire circumference substantially in the middle of the axial direction of the rotation support portion 15c. Packings 16 are mounted along the upper and lower sides of the convex portion 23, respectively. Also by this convex part 23, the foreign substance intrusion path between the packings 16, 16 and the rotation support part 15c is made into a maze structure, and the waterproof performance can be enhanced.
When the two groove portions 21 and 22 are provided in the rotation support portion 15c as described above (third embodiment), or when one convex portion 23 is provided (fourth embodiment), the shape is different from the packing 16. The waterproofing performance can be further improved by attaching the packing 17.

FIG. 7 shows the waterproof structure of the fifth embodiment. In the fifth embodiment, two groove portions 21 and 22 similar to those of the third embodiment are provided in the rotation support portion 15c in parallel with each other over the entire circumference. One packing 17 is mounted along the peripheral surface of the rotation support portion 15c in a state straddling the two groove portions 21 and 22. As shown in the figure, the packing 17 is a rubber ring having a U-shaped cross section, and is mounted in a state where L-shaped bent portions 17a and 17a on both sides in the width direction are fitted in the groove portions 21 and 21, respectively. The outer peripheral surface of the packing 17 is in sliding contact with the inner surface of the support recess 13a. The single packing 17 forms two maze structures as in the third embodiment, and the waterproof performance between the packing 17 and the rotation support portion 15c is enhanced. Moreover, according to this packing 17, since it is wider than the said packing 16 and the sliding contact area with respect to the inner surface of the support recessed part 13a becomes large, a higher waterproof function can be given also in this point.
FIG. 8 shows the waterproof structure of the sixth embodiment. In the sixth embodiment, one convex portion 23 similar to that of the fourth embodiment is provided on the rotation support portion 15c over the entire circumference. The same packing 17 as that of the fifth embodiment is mounted so as to cover the convex portion 23. In the case of the sixth embodiment, the packing 17 is mounted in a state where the convex portion 23 is sandwiched between the L-shaped bent portions 17a, 17a on both sides in the width direction. The outer peripheral side of the packing 17 is in sliding contact with the inner surface of the support recess 13a. Thus, by fitting both the L-shaped bent portions 17a and 17a into the convex portion 23, a labyrinth structure is formed between the packing 17 and the rotation support portion 15c, and the waterproof performance is enhanced.

FIG. 9 shows the waterproof structure of the seventh embodiment. In the seventh embodiment, as shown in the figure, a ring-shaped rubber ring is used, but a packing 18 having a groove portion 18a formed on the entire outer periphery thereof is used. This packing 18 is attached to the rotation support portion 15 c of the forward / reverse switching lever 15. In the case of the seventh embodiment, the turning support portion 15c is not provided with the groove portions 20 to 22 or the convex portion 23 described above. In the case of 7th Embodiment, the convex part 24 is provided in the inner surface of the support recessed part 13a of the switch case 13 over the perimeter. The packing 18 is slidably contacted with the inner surface of the support recess 13a in a state in which the projection 24 is fitted along the groove 18a of the packing 18. In the present embodiment, the convex portion 24 is fitted into the groove portion 18a, whereby a labyrinth structure is formed between the packing 18 and the support concave portion 13a, and the waterproof performance between the two is enhanced.
Thus, in addition to providing the groove portions 20 to 22 or the convex portion 23 on the rotation support portion 15c side, the foreign substance intrusion path can be made into a maze structure by providing the convex portion 24 on the support concave portion 13a side. Thus, high waterproof performance can be provided.
Contrary to the seventh embodiment, a convex portion is provided on the outer peripheral side of the packing, and this is fitted into a groove provided on the support concave portion 13a side, and a maze structure is formed between the packing and the support concave portion 13a. It is good also as a structure to make.
Further, the maze structure of the seventh embodiment can be combined with the maze structure of the second to sixth embodiments. That is, by providing a groove portion or a convex portion in both the rotation support portion 15c and the support concave portion 13a and fitting or fitting the packing into these, the gap between the packing and the rotation support portion 15c, and between the packing and the support concave portion. A labyrinth structure can be formed on both sides of the inner surface of 13a, whereby the waterproof performance can be further enhanced.

Next, FIG. 10 shows a waterproof structure according to the eighth embodiment. The eighth embodiment is characterized in that an elastomer resin layer 19 is integrally formed on the rotation support portion 15 instead of mounting the packing 16 (17, 18) on the rotation support portion 15 as a separate member. doing. When the forward / reverse switching lever 15 is molded, the elastomer resin layer 19 can be integrally formed and covered on the rotation support portion 15c by so-called two-color molding.
Although not shown, the elastomer resin layer may be covered on the support recess 13a side of the switch case 13 instead of or in addition to the elastomer resin layer on the rotation support portion 15 side.
Since the elastomer resin layer is integrally formed on the inner surface of the rotation support portion 15 and / or the support recess portion 13a in this way, the forward / reverse switching lever 15 and the packing can be handled as one part, so that the switch body The number of parts of 10 can be reduced and the assemblability can be improved.
Further modifications can be added to the eighth embodiment. For example, a convex portion can be provided on the peripheral surface of the elastomer resin layer 19 over the entire circumference, and this convex portion can be inserted into a groove portion provided on the support concave portion 13a side to form a similar maze structure, thereby further improving the waterproof performance. Can be increased. In addition, you may provide a convex part and a groove part reversely between the elastomer resin layer 19 and the support recessed part 13a.

FIG. 11 shows the waterproof structure of the ninth embodiment. In the waterproof structure of the ninth embodiment, instead of the rubber packing 16 (17, 18, 19), a packing 25 made of a water absorbing material is mounted on the rotation support portion 15c. As the water absorbing material, for example, an open-cell sponge material can be used. The packing 25 corresponds to an example of a water absorbing member described in the claims. Since the packing 25 having the water absorption function can also reduce or prevent the intrusion of foreign matters such as moisture into the switch case 13 through the support recess 13, the waterproof function of the rotation support portion can be enhanced as compared with the conventional case. Can do.
Similarly to the above embodiments, the packing 25 can be fitted in the groove or along the convex portion to form a maze structure for the intrusion path of the foreign matter, thereby obtaining higher waterproof performance.

As described above, according to each embodiment of the present invention, the packing 16 to 18 and 25 attached to the rotation support portion 15c of the forward / reverse switching lever 15 allows moisture, dust, etc. to enter the support recess 13a. Intrusion of foreign matter can be reduced or prevented, and as a result, entry of these foreign matter into the switch case 13 through the insertion window portion 13b is prevented.
Thus, since the waterproofing of the rotation support portion 15c of the forward / reverse switching lever 15 with respect to the rotation concave portion 13a of the switch case 13 is made by the packing 16, the waterproof performance of the switch body 10 can be enhanced compared to the conventional case. As a result, the durability can be enhanced.
Moreover, the groove | channel part 20, 21, 22 or the convex part 23 is provided in the rotation support part 15c, and the penetration | invasion path | route (immersion path | route) of the foreign material between packing 16,17 and the rotation support part 15c is made into the maze structure. Therefore, the waterproof performance can be further enhanced.
Further, as illustrated in the seventh embodiment, the convex portion 24 is provided on the inner surface of the support concave portion 13a over the entire circumference, and is fitted into the groove portion 18a of the packing 18, so that the gap between the packing 18 and the support concave portion 13a is provided. The maze is structured, and high waterproof performance can be obtained.

Each embodiment described above can be implemented with further modifications. For example, a configuration in which a groove 20 (21, 22) or a convex portion 23 is provided on the rotation support portion 15c side of the forward / reverse switching lever 15 to form a maze structure between the rotation support portion 15c and the packing 16 is illustrated. However, instead of this, or in addition to this, a similar groove or projection may be provided on the side of the support recess 13a so that a labyrinth structure is formed between the packing 16 and the support recess 13a.
Further, the forward / reverse switching lever 15 of the electric screw tightening machine 1 is illustrated as the lever of the electric tool, but the lever is not limited to the forward / reverse switching lever that switches the rotation direction of the electric motor, but is also applicable to a lever that switches other electric circuits. can do. Therefore, the electric screwdriver has been exemplified as the electric power tool. However, it is widely applied to the lever of the switch for switching the state by rotating the left and right or up and down at a certain angle in other electric tools such as an electric drill, a hammer drill, and a tabletop cutting machine. can do.
Further, as the packings 16, 17, and 18, rubber packings called so-called O-rings are illustrated, but packings (waterproof members) made of other elastic materials such as elastomer resin and single foam sponge are used. It is good also as a structure.
Furthermore, in the ninth embodiment, the continuous foam sponge material is exemplified as the water absorbing material, but the water absorbing material may be changed to another water absorbing material such as a felt material.

1 ... Electric screw tightening machine (electric tool)
2 ... Tool body 3 ... Handle 4 ... Electric motor 5 ... Battery pack 10 ... Switch body 11 ... Switch lever 12 ... Switch rod 13 ... Switch case 13a ... Support recess, 13b ... Insertion window 15 ... Forward / reverse switching lever 15a ... operating part, 15b ... actuating part, 15c ... rotation support part 16, 17, 18 ... packing (made of rubber)
19 ... Elastomer resin layers 20, 21, 22 ... Grooves 23, 24 ... Protrusions 25 ... Packing (water absorbing material)

Claims (9)

It is a waterproof structure for a switching operation lever provided on the switch body for switching the operation of the electric tool so that it can be rotated,
The lever includes an operation portion operated by a user, and said switch actuating portion to switch enters the body, another the pivot support portion that binds to the crank shape of the operation portion and the operation portion,該回A structure that is supported by a switch case of the switch body via a moving support portion so as to be rotatable, and has a waterproof function with respect to the switch case by mounting a packing on the rotating support portion. The waterproof structure according to claim 1, wherein a groove portion is provided in the rotation support portion over the entire circumference, and a packing is fitted into the groove portion, whereby a foreign substance intrusion path between the packing and the rotation support portion. Waterproof structure with a maze structure. 3. The waterproof structure according to claim 2, wherein two grooves are provided, and one packing is engaged with each groove. 3. The waterproof structure according to claim 2, wherein two grooves are provided, and both ends of one packing are engaged with each. The waterproof structure according to claim 1, wherein a convex portion is provided on the entire circumference of the rotation support portion, two packings are mounted along both sides of the convex portion, and the packing and the rotation support portion are provided. Waterproof structure with a maze structure for the foreign substance intrusion route between the two. The waterproof structure according to claim 1, wherein a convex portion is provided on the entire circumference of the rotation support portion, and a single packing is placed on the convex portion, and the foreign matter between the packing and the rotation support portion. Waterproof structure with a maze structure for the intrusion route. The waterproof structure according to claim 1, wherein an engagement groove is provided on an outer periphery of the packing, and an engagement protrusion provided on the switch case side is engaged with the engagement groove. A waterproof structure in which a foreign substance intrusion path between the packing and the switch case side is structured as a maze. It is a waterproof structure for a switching operation lever provided on the switch body for switching the operation of the electric tool so that it can be rotated,
The lever includes an operation portion operated by a user, and said switch actuating portion to switch enters the body, another the pivot support portion that binds to the crank shape of the operation portion and the operation portion,該回It is supported in a support recess of the switch body via a moving support part so as to be rotatable.
A structure in which an elastomer resin layer is integrally formed on the rotation support portion and / or the support recess to provide a waterproof function for the support recess of the lever. It is a waterproof structure for a switching operation lever provided on the switch body for switching the operation of the electric tool so that it can be rotated,
The lever includes an operation portion operated by a user, and said switch actuating portion to switch enters the body, another the pivot support portion that binds to the crank shape of the operation portion and the operation portion,該回A structure that is supported by a switch case of the switch body via a moving support portion so as to be able to rotate, and a water absorbing member is attached to the rotating support portion to provide a waterproof function for the switch case.

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